Isopropylmalate synthase regulatory domain removal abolishes feedback regulation at the expense of leucine homeostasis in plants

Abstract In the leucine (Leu) biosynthesis pathway, homeostasis is achieved through a feedback regulatory mechanism facilitated by the binding of the end product Leu at the C-terminal regulatory domain of the first committed enzyme, isopropylmalate synthase (IPMS). In vitro studies have shown that removing the regulatory domain abolishes the feedback regulation on plant IPMS while retaining its catalytic activity. However, the physiological consequences and underlying molecular regulation of Leu flux upon removing the IPMS regulatory domain remain to be explored in plants. Here, we removed the IPMS C-terminal regulatory domain using a CRISPR/Cas9-based gene editing system and studied the resulting impact on the Leu biosynthesis pathway under in planta conditions. Absence of the IPMS regulatory domain unexpectedly reduced the formation of the end product Leu but increased the levels of Leu pathway intermediates in mustard (Brassica juncea). Additionally, delayed growth was observed when IPMS devoid of the regulatory domain was introduced into IPMS-null mutants of Escherichia coli and Arabidopsis thaliana. Further, a detailed biochemical analysis showed that in the absence of the C-terminal regulatory domain, a Leu pathway intermediate (α-ketoisocaproate) could compete with the native IPMS substrate (2-oxoisovalerate) for the active site. Combining these metabolomic, biochemical, and in planta analyses, we demonstrate that the C-terminal regulatory domain of IPMS is critical for maintaining Leu–Val homeostasis in plants.